Escape mechanism for a wireless local area network

ABSTRACT

A method for performing frequency selection escape in wireless communications is disclosed. The method includes receiving an activation trigger, determining whether the activation trigger has persisted for a predetermined period of time, determining a list of candidate channels; selecting a channel from the candidate list, and evaluating the selected channel against predetermined criteria, the predetermined criteria being related to the activation trigger. If the selected channel meets the predetermined criteria, then an access point (AP) is disassociated from all stations communicating with the AP; and the AP is changed to the selected channel. If the selected channel does not meet the predetermined criteria, then the selected channel is removed from the candidate list; and the selecting of a channel is repeated if there are additional candidate channels.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 10/942,576, filed Sep. 16, 2004, which claims the benefit of U.S. Patent Application No. 60/535,429, filed Jan. 8, 2004, both of which are incorporated by reference as if fully set forth herein.

FIELD OF INVENTION

The present invention relates to wireless local area networks (WLANs) and, more particularly, to a method for alleviating congestion and interference levels in a WLAN by changing the channel currently in use.

BACKGROUND

A frequency selection algorithm is used to automatically select the most appropriate operating frequency for an access point (AP) in a WLAN. Frequency selection (FS) is typically composed of three distinct processes: initial FS, optimization FS, and escape FS. The initial FS process determines the best operating channel upon AP startup. The optimization FS process dynamically determines the optimal operating channel during system operation, without service disruption to associated wireless terminals (stations) in the basic service set (BSS). The process waits until there is no activity in the BSS for a certain period of time before changing the operating channel to a less loaded one.

The escape FS process is used to alleviate extreme congestion situations or intolerable interference levels. The escape FS process will only be invoked if the service degradation due to congestion or interference is worse than the harm resulting from service disruption to all associated stations, because all associated stations must first be disassociated from the AP prior to escaping to a different channel. The present invention relates to the escape FS process.

SUMMARY

A method for performing frequency selection escape in wireless communications is disclosed. The method includes receiving an activation trigger, determining whether the activation trigger has persisted for a predetermined period of time, determining a list of candidate channels; selecting a channel from the candidate list, and evaluating the selected channel against predetermined criteria, the predetermined criteria being related to the activation trigger. If the selected channel meets the predetermined criteria, then an access point (AP) is disassociated from all stations communicating with the AP; and the AP is changed to the selected channel. If the selected channel does not meet the predetermined criteria, then the selected channel is removed from the candidate list; and the selecting of a channel is repeated if there are additional candidate channels.

BRIEF DESCRIPTION OF THE DRAWINGS

A more detailed understanding of the invention may be had from the following description of a preferred embodiment, given by way of example, and to be understood in conjunction with the accompanying drawings wherein:

FIGS. 1A and 1B show a flowchart of a method for an escape FS process in accordance with the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The inputs and parameters used by an escape FS process in accordance with the present invention are listed in Table 1.

TABLE 1 Inputs and parameters of the escape FS process Default Symbol Description Type Value ACS Allowable channel set. Configuration {1, 6, 11} parameter op_chan Index of the current operating Internal NA channel within the ACS. parameter T_(Last) The minimum elapsed time since the Configuration 300 seconds last invocation of any of the FS parameter algorithms for triggering escape FS. BO_(MIN) The lower bound on the random Configuration 10 seconds persistence timer for triggering parameter escape FS. BO_(MAX) The upper bound on the random Configuration 100 seconds persistence timer for triggering parameter escape FS. DR_(MAX) Deferral Rate triggering threshold. Configuration 30% parameter PER_(MAX) Transmitted packet error rate Configuration 6% triggering threshold. parameter CU_(MAX) Out-of-BSS channel utilization Configuration 40% triggering threshold. parameter DR Deferral rate. This is a measurement Measurement NA that represents the percentage of time that the AP is carrier locked (i.e., is not receiving any packets) and has at least one packet to transmit. The DR measurement is calculated as the total amount of time that the AP deferred transmission over the last T_(MEAS) seconds, divided by T_(MEAS) seconds. DR is calculated every T_(MEAS) seconds. PER Transmitted Packet Error Rate. This Measurement NA measurement is a ratio of the number of transmission failures (i.e., transmitted packets for which an ACK is not received) to the total number of transmitted packets including retransmissions, calculated over T_(MEAS) seconds. PER is calculated every T_(MEAS) seconds. C(k) The average channel utilization of Measurement NA channel k. C(k) is a moving average of the latest channel utilization measurement on each channel. The channel utilization measurement corresponds to the percentage of time that the receiver is carrier locked. The channel utilization estimates can be obtained by intermittently listening to these frequency channels for short periods of time (referred to as Silent Measurement Periods (SMP)), so that normal communications associated with the AP are not substantially disrupted. C(k) consists of an average over N_(SMP) SMP measurements. I[ ] The set of external interference Measurement NA measurements recorded during a given measurement period of T_(MEAS). The external interference measurement consists of the received signal power in the absence of “carrier lock” by the receiver. All external interference measurements that are provided by the chipset are recorded during a given measurement period. I_(SMP)(k) The average external interference Measurement NA level measured on the channel k. I_(SMP)(k) is measured as the average received signal power in the absence of “carrier lock” by the receiver (i.e., the receiver is not receiving any packets). I_(SMP)(k) consists of an average over N_(SMP) SMP measurements. L L represents the own-BSS load, Measurement NA observed over a measurement period of T_(MEAS) seconds. The own-BSS load consists of the sum of the medium usage time of successfully transmitted packets and successfully received packets from associated stations (own-BSS). L is calculated every T_(MEAS) seconds. T_(MEAS) Measurement period over which DR Configuration 1 second and PER measurements are parameter calculated. N_(SMP) Number of SMPs over which C(k) is Configuration 5 averaged. parameter RNG_(base) Baseline Range (set by the Path Loss Internal NA Discovery process). parameter RNG_(adj) Range Adjustment (set by the Load Internal NA Balancing process). parameter (C/I)_(req) _(—) _(high) Minimum required carrier power to Configuration 10 dB interference ratio to support the parameter planned data rate at the coverage bound. P_(MAX) Maximum AP transmission power. Configuration 20 dBm parameter I_(MAX) The maximum allowed interference Internal NA on any given channel determined parameter based on baseline range. M_(I) Interference margin used in the Configuration 3 dB calculation of the maximum allowable parameter interference level, I_(MAX.) M_(L) Load margin used in the interference Configuration 1.0 trigger of the algorithm. parameter Δ The amount, in dB, by which the Configuration 3 dB maximum allowed interference, I_(MAX,) parameter is increased if there are no candidate channels for which I < I_(MAX). H_(C) ^(Esc) Hysteresis criterion for channel Configuration 10% utilization. The difference between parameter the channel utilization of the current channel and the new channel must exceed this threshold. H_(I) ^(Esc) Hysteresis criterion for measured Configuration 3 dB interference level. The difference parameter between the interference on the current channel and the new channel must exceed this threshold. N_(RT) _(x) Number of retransmissions of the Configuration 1 Disassociate message to a particular parameter station before abandoning.

The transmit packet error rate, PER, is calculated over all medium access control (MAC) protocol data units (MPDUs) containing data, i.e., all fragments in the case of fragmentation, and all retransmissions. Moreover, a request to send (RTS) message for which a clear to send (CTS) message is not received should be included in the calculation of the transmitted packet error rate. In the event that zero packets were transmitted during the T_(MEAS) measurement period, the PER is set to zero.

Triggering (Start Stage)

The escape FS process is executed only during excessively high congestion situations or when interference is intolerable. Either one of the following triggering criteria, evaluated every T_(MEAS) seconds, must be satisfied to invoke the escape FS process.

The first triggering criterion is a channel congestion criterion, in which the following three conditions are satisfied:

1) C(op_chan)>CU_(MAX);

2) DR>DR_(MAX); and

3) PER>PER_(MAX).

The out-off-BSS channel utilization measurement, the AP deferral rate, and the transmitted packet error rate must exceed their respective triggering thresholds. It is noted that the out-of-BSS channel utilization measurements can be obtained by intermittently listening to the different frequency channels for short periods of time, i.e., Silent Measurement Periods (SMP), so that normal communications associated with the AP are not substantially disrupted.

These three metrics were carefully chosen to ensure that the escape FS algorithm only triggers when a change of channel is required and beneficial. First, the out-of-BSS channel utilization metric is used to ensure that the channel congestion is caused, at least in part, by out-of-BSS WLAN traffic. If the congestion were caused only by in-BSS traffic, a change of channel would not alleviate the congestion situation because all of the traffic would be moved to the new channel. Second, the deferral rate measurement is considered to ensure that the AP effectively perceives the congestion; a high deferral rate indicates that the AP has a significant amount of data to transmit and is experiencing significant delays for channel access. Third, the packet error rate must exceed its triggering threshold.

The second triggering criterion corresponds to an intolerable interference level. Many external interference sources, such as a microwave oven, exhibit intermittent interference patterns. As a result, the effect of the interference source depends on the proportion of time that the intolerable interference persists, as well as the traffic load of the AP.

Let PI represent the proportion of time that the external interference level is intolerable over a given measurement period:

$\begin{matrix} {{PI} = \frac{{Size}\left( {{I{\lbrack\rbrack}} > I_{MAX}} \right)}{{Size}\left( {I{\lbrack\rbrack}} \right)}} & {{Equation}\mspace{14mu} (1)} \end{matrix}$

where the determination of I_(MAX) is described later.

The following triggering criterion is defined:

(1−CU(op _(—) chan))×(1−PI)≦(L×M _(L))  Equation (2)

The left-hand side of Equation (2), (1−CU(op_chan))×(1−PI), effectively represents the “good bandwidth” that is available for own-BSS transmission, whereas the right-hand side represents the BSS load. The escape FS algorithm will only trigger if the intolerable interference occupies so much bandwidth that there is not enough interference-free bandwidth for the AP to serve its load.

Along with the triggering criteria described above, at least T_(Last) seconds must have elapsed since the last execution of either initial FS, optimization FS, or escape FS; otherwise, the triggering condition is ignored. The value of T_(Last) is the same as for the optimization FS algorithm. Once T_(Last) has expired since a channel change, the two triggering conditions are evaluated periodically over T_(MEAS).

Moreover, the triggering criteria must persist for at least T_(Trigger) seconds in order to allow a frequency change. The duration of the required persistence time, T_(Trigger), is generated as a random variable that is uniformly distributed between BO_(MIN) and BO_(MAX), in discrete steps of T_(MEAS). The use of a random timer results in a back-off procedure, which ensures that two competing BSSs on the same channel do not escape at the same time.

Both triggering criteria, along with BO_(MIN), should be carefully set to avoid premature channel changes. The escape FS process is considered as a last resort, because all associated stations must first be disassociated prior to changing the channel, resulting in an interruption of service. The channel should only be changed if the current external loading and/or external interference are unsupportable, in which case it is worth interrupting service to all stations. Finally, BO_(MAX) should be set high enough to yield a small probability of having multiple APs simultaneously escaping, and low enough to ensure a quick response by the escape FS process.

A flowchart of the escape FS process 100 is illustrated in FIGS. 1A and 1B. The escape FS process 100 can be performed by an AP. The components of the AP performing the escape FS process 100 can be an integrated circuit (IC), such as an application specific IC (ASIC), multiple ICs, discrete components, or a combination of discrete components and IC(s). Upon triggering the escape FS process, a set of candidate channels is first determined, followed by channel selection and channel update (if required).

Determining Candidate Channels

The set of candidate channels does not consist of the all channels in the allowable channel set (ACS). Only channels for which the interference measurement, I, lies below the maximum allowed interference level, I_(MAX), are considered; those with interference levels above I_(MAX) are ignored. The escape FS process 100 begins by retrieving data from power control and then calculating the value I_(MAX) (step 102). The initial maximum allowed interference level is calculated as:

I _(MAX) =P _(MAX)−(RNG _(base) +RNG _(adj))−(C/I)_(req) _(—) _(high) −M _(I)  Equation (3)

where (RNG_(base)+RNG_(adj)) represents the range covered by the AP and (C/I)_(req) _(—) _(high) is set to the required carrier power to interference ratio of a packet at the planned rate at BSS range (i.e., 5.5 or 11 Mbps). A margin, M_(I), is subtracted to eliminate channels with interference levels too close to the actual maximum allowed level.

The current channel is removed from the ACS (step 104), because the process is looking to escape from the current channel. The first channel from the ACS is selected (step 106). The interference measured on the selected channel is compared to the maximum allowed interference (step 108). If the interference on the current channel is less than the maximum interference, then the current channel is recorded in the candidate channel list (step 110).

If the interference on the current channel exceeds the maximum interference (step 108) or if the channel is recorded in the candidate list (step 110), a determination is then made whether there are more channels in the ACS (step 112). If there are more channels in the ACS, then the next channel is selected (step 114) and is evaluated at step 108 as described above.

If there are no more channels in the ACS (step 112), a determination is made whether there are any channels in the candidate list (step 116). If there are no channels in the candidate list, i.e., I(k)>I_(MAX) for all k, then the value of I_(MAX) is increased by a predetermined amount (Δ dB; step 118), and a new list of candidate channels is generated by re-running the process starting at step 106. The process is continued until a candidate list containing at least one channel is found. Δ should be set such that all channels with similar interference levels are considered as candidates; any value for Δ greater than zero is acceptable.

If there are channels in the candidate list (step 116), then the process continues with the channel selection and channel update stages.

Channel Selection and Channel Update

From the candidate list, the channel with the lowest average channel utilization C(k) is selected (step 120). Channel selection amongst candidate channels is primarily based on recent channel utilization measurements. The channel utilization of channel k, C(k), is an average of the latest channel utilization measurements on each channel. Channel utilization measurements are performed during the silent measurement periods (SMPs) and correspond to the percentage of time that the receiver is carrier locked. Since channel utilization is observed during SMPs, all packets that cause the AP to carrier lock originate from neighboring BSSs. The channel utilization measurement represents the out-of-BSS channel usage.

A decision is made to determine which of the trigger criteria was met to activate the process 100 (step 122). If the trigger was (1; channel congestion), then a determination is made whether the channel utilization of the selected channel is lower than the channel utilization of the current channel by a predetermined amount (step 124). Based on the triggering criterion, a hysteresis criterion is verified. For trigger (1), the hysteresis criterion is defined as:

C(op _(—) chan)−C(new_channel)>H _(C) ^(Esc)  Equation (4)

The channel utilization of the new channel must be lower than the channel utilization of the current channel by at least H_(C) ^(Esc) %. If this condition is met, then the BSS channel is updated with the new channel. All of the stations associated with the AP are disassociated (step 126). The AP first sends a Disassociation message to each associated station, and then change its frequency to the new frequency. In the case where a Disassociation message is sent to a station and no ACK is received, the AP will retransmit the message up to N_(RTx) times before abandoning the disassociation of this particular station. It is noted that the likelihood of transmission failure of a Disassociation message should be high given the severity of conditions under which the escape FS process is triggered.

The AP changes to the new channel (step 128), and the process terminates (step 130). The disassociated stations will then reassociate with the AP, per known procedures.

If the channel utilization of the selected channel is not lower than the channel utilization of the current channel by a predetermined amount (step 124), then the selected channel is removed from the list of candidate channels (step 132). Next, a determination is made whether there are any more channels in the candidate list (step 134). If there are more candidate channels, then the process continues with step 120 as described above. If there are no more candidate channels (step 134), then no change of channel is made (step 136) and the process terminates (step 130). This process continues until a candidate channel that satisfies the hysteresis criterion is found or there are no remaining candidate channels.

If the escape FS algorithm 100 was activated by trigger (2; intolerable interference) (step 122), then a determination is made whether the interference on the selected channel is lower than the interference on the current channel by a predetermined amount (step 138). For trigger (2), the hysteresis criterion is defined as:

I(op _(—) chan)−I(new_channel)>H _(I) ^(Esc)  Equation (5)

The interference level of the new channel must be lower than the interference level of the current channel by at least H_(I) ^(Esc) dB. The hysteresis criterion is used to ensure that change of channel will be beneficial enough to justify the service interruption to associated stations.

If this condition is met, then the process 100 continues with step 126, as described above. If this condition is not met, then the process 100 continues with step 132, as described above.

The following features need to be supported by the AP in order to perform the escape FS process 100:

1) Transmitted packet error rate measurement with configurable averaging window size. Alternatively, the AP can provide an indication for each successful and failed packet transmission.

2) Received packet error rate measurement with configuration averaging window size. Alternatively, the AP can provide an indication for each successful and failed packet reception.

3) The Deferral Rate measurement, which corresponds to the percentage of time that the AP is carrier locked by an out-of-BSS packet and has at least one packet to transmit.

4) Channel utilization during a silent measurement period, which corresponds to the percentage of time that the receiver is carrier locked.

5) External interference measurement, which corresponds to the average received signal power in the absence of carrier lock by the receiver.

6) Number of retransmissions of a particular packet.

7) Dynamic setting/update of the operating channel.

In other embodiments, additional modifications could be made to the present invention to better alleviate congestion and high interference levels in the WLAN. For example, the AP can inform stations of a change of operating frequency to eliminate the need for disassociating them. The optimization FS process can thus run periodically, without any concern for activity on the channel, eliminating the need for a separate escape FS process. Another modification would be to employ a centralized scheme, where channel assignment is determined on a network basis rather than independently for each BSS, which improves overall system performance. Furthermore, inter-AP communication would allow APs to share load information and notification of a change in frequency. In some WLAN settings, such as a MESA setting, the WLAN does not support inter-AP communication.

Although the features and elements of the present invention are described in the preferred embodiments in particular combinations, each feature or element can be used alone (without the other features and elements of the preferred embodiments) or in various combinations with or without other features and elements of the present invention. While specific embodiments of the present invention have been shown and described, many modifications and variations could be made by one skilled in the art without departing from the scope of the invention. The above description serves to illustrate and not limit the particular invention in any way. 

1. A method for performing frequency selection escape in wireless communications, comprising: receiving an activation trigger; determining whether the activation trigger has persisted for a second predetermined period of time; determining a list of candidate channels; selecting a channel from the candidate list; evaluating the selected channel against predetermined criteria, the predetermined criteria being related to the activation trigger; and if the selected channel meets the predetermined criteria, then disassociating an access point (AP) from all stations communicating with the AP; and changing the AP to the selected channel; if the selected channel does not meet the predetermined criteria, then removing the selected channel from the candidate list; and repeating the selecting of a channel if there are additional candidate channels.
 2. The method according to claim 1, wherein the activation trigger is received when a channel congestion condition exists.
 3. The method according to claim 2, wherein a channel congestion condition exists when: an average channel utilization of a current channel exceeds a maximum channel utilization threshold; a packet deferral rate exceeds a maximum deferral rate; and a transmission packet error rate exceeds a maximum packet error rate.
 4. The method according to claim 2, wherein the evaluating includes: measuring a channel utilization of the selected channel; and comparing a channel utilization of the selected channel with a channel utilization of the current channel, whereby the selected channel meets the criteria if the channel utilization of the selected channel is less than the channel utilization of the current channel by a predetermined amount.
 5. The method according to claim 1, wherein the activation trigger is received when an intolerable interference level exists.
 6. The method according to claim 5, wherein an intolerable interference level exists when an external interference level exceeds a maximum interference level.
 7. The method according to claim 5, wherein the evaluating includes: measuring an interference level of the selected channel; and comparing the interference level of the selected channel with an interference level of a current channel, whereby the selected channel meets the criteria if the interference level of the selected channel is less than the interference level of the current channel by a predetermined amount.
 8. The method according to claim 1, wherein the determining includes: selecting a channel from an allowable channel set (ACS); measuring the interference of the selected channel; comparing the interference of the selected channel with a maximum interference value; and adding the selected channel to the list of candidate channels if the interference of the selected channel is less than the maximum interference value.
 9. The method according to claim 8, wherein the ACS does not include a current channel.
 10. The method according to claim 8, wherein if all channels in the ACS have been examined and the candidate list is empty, then: increasing the maximum interference value by a predetermined amount; and repeating the determining.
 11. The method according to claim 1, wherein the selecting includes selecting a channel with a lowest average channel utilization.
 12. The method according to claim 1, further comprising: reassociating the AP and the stations, the reassociating being performed after the changing.
 13. The method according to claim 1, further comprising: waiting for a first predetermined period of time after a prior channel change. 